CN217995999U - Bimetallic strip feeding device - Google Patents

Abstract

The utility model discloses a bimetallic strip feed arrangement, this device include feeding mechanism, guide rail mechanism, move material mechanism, processing tool, and feeding mechanism, processing tool are located guide rail mechanism's both ends respectively, move material mechanism and locate guide rail mechanism, processing tool between the top position. The guide rail mechanism comprises a guide rail, and the guide rail is obliquely arranged; the material moving mechanism is provided with a material sucking assembly capable of driving rotation. In the device, a feeding mechanism provides a workpiece, the workpiece is conveyed to the front end of the processing jig along with the guide rail mechanism, and the workpiece is input into the processing jig by the material moving mechanism. The guide rail is the slope setting, and the foil is carried with the form of slope, and the work piece of slope can conveniently inhale the absorption of material subassembly, consequently, can guarantee to move the material success rate that moves of material mechanism to improve the feeding stability of this device.

Description

Bimetallic strip feeding device

Technical Field

The utility model relates to an automated processing technical field, in particular to bimetallic strip feed arrangement.

Background

The temperature controller is widely applied to various household electrical appliances, such as a water heater, a water dispenser, a refrigerator and the like, can rapidly make corresponding actions according to the change of environmental temperature, and mainly comprises a shell and a surface cover, wherein a bimetallic strip and an insulating strip are arranged in the shell.

In the production process of the existing temperature controller, the bimetallic strip is conveyed to the horizontally arranged feeding rail through the vibrating disc, and then the bimetallic strip is taken out from the feeding rail by the manipulator, but the feeding of the vibrating disc-feeding rail with the structure is unstable, so that the problems that the bimetallic strip is sucked and dropped and the like sometimes occur, or the problems that the bimetallic strip cannot be accurately sucked and the like occur.

SUMMERY OF THE UTILITY MODEL

According to an aspect of the present invention, there is provided a bimetal feeding device, including

A feed mechanism configured to provide a workpiece;

one end of the guide rail mechanism is connected with the discharge end of the feeding mechanism;

the processing jig is positioned at the other end of the guide rail mechanism and connected with the other end of the guide rail mechanism;

a material moving mechanism arranged at the upper position between the guide rail mechanism and the processing jig,

the guide rail mechanism comprises a guide rail, and the guide rail is obliquely arranged; the material moving mechanism is provided with a material sucking assembly capable of driving rotation.

The utility model provides a can carry out the automation equipment of feeding to foil. In the device, a feeding mechanism provides a workpiece, the workpiece is conveyed to the front end of a processing jig along with a guide rail mechanism, and the workpiece is input into the processing jig by a material moving mechanism. The guide rail is the slope setting, and the foil is carried with the form of slope, and the work piece of slope can conveniently inhale the absorption of material subassembly, consequently, can guarantee to move the material success rate that moves of material mechanism to improve the feeding stability of this device.

In some embodiments, the material moving mechanism comprises a rack, a rotary driving assembly, a first movable driving assembly and a second movable driving assembly, wherein the rotary driving assembly is arranged on the rack, the first movable driving assembly is arranged at the driving end of the rotary driving assembly, the second movable driving assembly is arranged at the driving end of the first movable driving assembly, and the material sucking assembly is arranged at the driving end of the second movable driving assembly.

From this, in moving material mechanism, the rotary drive subassembly is responsible for inhaling the rotary drive of material subassembly, and first removal drive subassembly then is responsible for inhaling the horizontal drive of material subassembly, and the second removes the vertical drive that the drive subassembly then was responsible for inhaling the material subassembly.

In some embodiments, the rotary drive assembly includes a mounting plate rotatably disposed on the frame, and a rotary drive member disposed on the frame and drivingly connected to the mounting plate.

Thereby, the rotary driving member drives the mounting plate to rotate.

In some embodiments, the first movement driving assembly includes a first driving member and a sliding plate, a first sliding rail extending horizontally is disposed on one end surface of the mounting plate, the sliding plate is mounted on the first sliding rail, the first driving member is disposed on the other end surface of the mounting plate, and a driving end of the first driving member is connected to the sliding plate through a connecting frame.

Thereby, the first driving piece drives the sliding plate to move transversely on the first sliding rail.

In some embodiments, the second moving driving assembly includes a second driving member and a lifting plate, a second sliding rail extending vertically is disposed on the sliding plate, the lifting plate is mounted on the second sliding rail, the second driving member is disposed on the sliding plate and located at an upper end of the second sliding rail, and a driving end of the second driving member is connected to the lifting plate.

Therefore, the first driving piece drives the lifting plate to vertically move on the second sliding rail.

In some embodiments, the material moving mechanism further comprises two first buffer assemblies, the two first buffer assemblies are arranged on the rack, the two first buffer assemblies are respectively located at two ends of the first sliding rail, and the two first buffer assemblies can be separated and abutted against the mounting plate.

Thereby, the buffer member can buffer the slide plate.

In some embodiments, the material moving mechanism further includes a second buffer component, the second buffer component is disposed on the sliding plate and located at the upper end of the second sliding rail, and the second buffer component is detachably abutted to the lifting plate.

From this, the buffer unit can cushion the lifter plate.

In some embodiments, the guide rail mechanism further comprises a limiting assembly, a material preparation station is arranged at one end of the guide rail close to the material moving mechanism, and the limiting assembly is arranged on the front side of the material preparation station.

In this way, as a dividing action, only one workpiece is allowed to be introduced into the preparation station at a time.

In some embodiments, the limiting assembly comprises a fourth driving member, a top pillar and a pushing pillar, the top pillar is slidably arranged on the end surface of the guide track, the fourth driving member is fixed on one side of the guide track, the pushing pillar is arranged at the driving end of the fourth driving member, the pushing pillar is matched with the top pillar,

the pushing column is abutted against the ejection column through the driving of the fourth driving piece, so that the ejection column penetrates through the guide rail and protrudes out of the end face of the guide rail.

Therefore, when materials exist in the material preparation station, the ejection column is in contact with the push column, the upper end of the ejection column penetrates through the guide rail, and the workpieces are prevented from entering the material preparation station.

In some embodiments, the lower end of the top pillar is provided with a first inclined surface, and the upper end of the push pillar is provided with a second inclined surface matched with the first inclined surface.

Therefore, the top column is protruded or retracted in a mode that the first inclined surface is abutted against or separated from the second inclined surface.

Drawings

Fig. 1 is a schematic perspective view of a bimetallic strip feeding device according to an embodiment of the present invention.

Fig. 2 is a schematic top view of the sheet metal slide feeder shown in fig. 1.

Fig. 3 is a schematic perspective view of a material moving mechanism in the metal sheet sliding feeding device shown in fig. 1.

Fig. 4 isbase:Sub>A schematic sectional view along the directionbase:Sub>A-base:Sub>A in fig. 2.

Fig. 5 is a partially enlarged schematic view of fig. 4.

The reference numbers in the figures: 100-feeding mechanism, 200-guide rail mechanism, 210-guide rail, 211-material preparing station, 220-limiting component, 221-fourth driving component, 222-top column, 223-pushing column, 2221-first inclined plane, 2231-second inclined plane, 300-material moving mechanism, 310-material sucking component, 320-rack, 330-rotary driving component, 331-mounting plate, 4332-rotary driving component, 340-first movable driving component, 341-first driving component, 342-sliding plate, 343-connecting rack, 350-second movable driving component, 351-second driving component, 352-lifting plate, 360-first sliding rail, 370-second sliding rail, 380-first buffering component, 390-second buffering component and a-workpiece.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1-2 schematically show a foil (bi-metal) feeding device according to an embodiment of the invention. As shown in the figure, the device includes feeding mechanism 100, guide rail mechanism 200, material moving mechanism 300, processing tool, feeding mechanism 100, processing tool are located the both ends of guide rail mechanism 200 respectively, material moving mechanism 300 locates the top position between guide rail mechanism 200, the processing tool. The feed mechanism 100 is configured to provide a workpiece a; the guide rail mechanism 200 is configured to guide the feeding of the workpiece a; the material moving mechanism 300 is configured to move the workpiece a from the guide rail mechanism 200 to the processing jig; the processing jig is configured to move the workpiece a to the processing station. The guide rail mechanism 200 and the processing jig are located on the same straight line.

The guide rail mechanism 200 includes a guide rail 210, and the guide rail 210 is disposed obliquely; the material moving mechanism 300 is provided with a material sucking component 310 capable of driving rotation.

In particular, the device is mainly directed to the feeding of bimetallic strips.

In the present apparatus, a workpiece a is supplied from a supply mechanism 100, and the workpiece a is conveyed to the front end of the processing jig along with a guide rail mechanism 200, and is input into the processing jig by a material transfer mechanism 300. The guide rail is the slope setting, and the foil is carried with the form of slope, and the work piece a of slope can conveniently inhale the absorption of material subassembly 310, consequently, can guarantee to move material mechanism 300 move the material success rate to improve the feeding stability of this device.

Referring to fig. 3, the material moving mechanism 300 includes a frame 320, a rotation driving assembly 330, a first movement driving assembly 340, and a second movement driving assembly 350, wherein the rotation driving assembly 330 is disposed on the frame 320, the first movement driving assembly 340 is disposed at a driving end of the rotation driving assembly 330, the second movement driving assembly 350 is disposed at a driving end of the first movement driving assembly 340, and the material sucking assembly 310 is disposed at a driving end of the second movement driving assembly 350.

In the material moving mechanism 300, the rotary driving assembly 330 is responsible for the rotary driving of the material sucking assembly 310, the first movable driving assembly 340 is responsible for the transverse driving of the material sucking assembly 310, and the second movable driving assembly 350 is responsible for the vertical driving of the material sucking assembly 310.

Referring to fig. 3, the rotation driving assembly 330 includes a mounting plate 331 and a rotation driving element 4332, the mounting plate 331 is rotatably disposed on the frame 320, and the rotation driving element 4332 is disposed on the frame 320 and is drivingly connected to the mounting plate 331. The rotary drive 4332 drives the mounting plate 331 to rotate.

Referring to fig. 3, the first moving driving assembly 340 includes a first driving member 341 and a sliding plate 342, a first sliding rail 360 extending horizontally is disposed on one end surface of the mounting plate 331, the sliding plate 342 is mounted on the first sliding rail 360, the first driving member 341 is disposed on the other end surface of the plate, and a driving end of the first driving member 341 is connected to the sliding plate 342 through a connecting frame 343. The first driving member 341 drives the sliding plate 342 to move laterally on the first sliding rail 360.

Referring to fig. 3, the second moving driving assembly 350 includes a second driving element 351 and a lifting plate 352, a second sliding rail 370 extending vertically is disposed on the sliding plate 342, the lifting plate 352 is mounted on the second sliding rail 370, the second driving element 351 is disposed on the sliding plate 342 and located at the upper end of the second sliding rail 370, and a driving end of the second driving element 351 is connected to the lifting plate 352. The first driving member 341 drives the lifting plate 352 to move vertically on the second sliding rail 370.

With reference to fig. 3, the material moving mechanism 300 further includes two first buffer assemblies 380, the two first buffer assemblies 380 are both disposed on the frame 320, the two first buffer assemblies 380 are respectively located at two ends of the first slide rail 360, and the two first buffer assemblies 380 are separable and offset from the mounting plate 331. The buffer member can buffer the sliding plate 342.

Referring to fig. 3, the material moving mechanism 300 further includes a second buffer assembly 390, the second buffer assembly 390 is disposed on the sliding plate 342 and located at the upper end of the second sliding rail 370, and the second buffer assembly 390 is separable and butts against the lifting plate 352. The buffer assembly is capable of buffering the lift plate 352.

In this embodiment, the rotary driving member 4332 is a pneumatic motor, the first driving member 341 is a cylinder driven linearly, and the second driving member 351 is also a cylinder driven linearly.

In this embodiment, the material sucking component 310 is a negative pressure sucking head.

With reference to fig. 4-5, the guide rail mechanism 200 includes a limiting component 220 and a guide rail 210, the guide rail 210 is disposed obliquely, a material preparation station 211 is disposed at one end of the guide rail 210 close to the material moving mechanism 300, and the limiting component is disposed at a front side of the material preparation station 211. As a divide action, only one workpiece a is allowed to enter the preparation station 211 at a time.

With reference to fig. 4-5, the limiting assembly 220 includes a fourth driving member 221, a top pillar 222, and a pushing pillar 223, the top pillar 222 is slidably disposed on the end surface of the guide track 210, the fourth driving member 221 is fixed on one side of the guide track 210, the pushing pillar 223 is disposed at a driving end of the fourth driving member 221, the pushing pillar 223 is matched with the top pillar 222, and the pushing pillar 223 abuts against the top pillar 222 by driving of the fourth driving member 221, so that the top pillar 222 penetrates through the guide track 210 and protrudes out of the end surface of the guide track 210. When the material is present at the preparation station 211, the top pillar 222 contacts the push pillar 223, and the upper end of the top pillar 222 penetrates the guide rail 210, so that the workpiece a is prevented from entering the preparation station 211.

Referring to fig. 4 to 5, the top post 222 is provided at a lower end thereof with a first inclined surface 2221, and the pushing post 223 is provided at an upper end thereof with a second inclined surface 2231 matched with the first inclined surface 2221. The top post 222 is projected or retracted by the first inclined surface 2221 coming into contact with or separating from the second inclined surface 2231.

In this embodiment, the fourth driver 221 is a linear driving cylinder.

Preferably, the feeding mechanism 100 is a vibrating disk. The material is supplied by a vibration disc mode.

The application of this device uses this device on disc processing equipment, specifically as follows, and processing equipment includes feed arrangement, still includes board, processingequipment, discharging device, disc device, and feed arrangement, processingequipment, discharging device, disc device all locate on the board, and feed arrangement, processingequipment, discharging device are located around the disc device, and processing tool 300 circumference array is on the border of disc device.

The disc processing apparatus works as follows:

s1, feeding:

the feeding mechanism 100 feeds a workpiece a; the workpiece a enters the guide rail mechanism 200 and is conveyed by the guide rail mechanism 200, and when the workpiece a enters; the material moving mechanism 300 is started, the rotary driving element 4332, the first driving element 341 and the second driving element 351 jointly drive the material suction assembly 310 to approach the workpiece a, and the material suction assembly 310 sucks the workpiece a; the rotary driving element 4332, the first driving element 341 and the second driving element 351 jointly drive the suction assembly 310 to approach the processing fixture, and the suction assembly 310 releases the workpiece a on the processing fixture.

(work a is carried to the working end of each apparatus along with the disk apparatus)

And S2, processing the workpiece a by the processing device.

S3, discharging, wherein the discharging device discharges the workpiece a.

What has been described above is merely some embodiments of the present invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. The bimetallic strip feeding device is characterized by comprising

A feeding mechanism (100) configured to supply a workpiece (a);

one end of the guide rail mechanism (200) is connected with the discharge end of the feeding mechanism (100);

the processing jig is positioned at the other end of the guide rail mechanism (200) and connected with the other end of the guide rail mechanism;

a material moving mechanism (300) which is arranged at the upper position between the guide rail mechanism (200) and the processing jig,

the guide rail mechanism (200) comprises a guide rail (210), and the guide rail (210) is obliquely arranged; the material moving mechanism (300) is provided with a material sucking component (310) capable of driving to rotate.

2. The bimetallic strip feeding device according to claim 1, wherein the material moving mechanism (300) includes a frame (320), a rotation driving assembly (330), a first movement driving assembly (340), and a second movement driving assembly (350), the rotation driving assembly (330) is disposed on the frame (320), the first movement driving assembly (340) is disposed at a driving end of the rotation driving assembly (330), the second movement driving assembly (350) is disposed at a driving end of the first movement driving assembly (340), and the material sucking assembly (310) is disposed at a driving end of the second movement driving assembly (350).

3. The bimetallic feeder of claim 2, wherein the rotary drive assembly (330) includes a mounting plate (331), a rotary drive member (4332), the mounting plate (331) being rotatably mounted to the frame (320), the rotary drive member (4332) being mounted to the frame (320) and being drivingly connected to the mounting plate (331).

4. The bimetallic feeding device according to claim 3, characterized in that the first movable driving assembly (340) comprises a first driving member (341) and a sliding plate (342), a first sliding rail (360) extending horizontally is arranged on one end surface of the mounting plate (331), the sliding plate (342) is mounted on the first sliding rail (360), the first driving member (341) is arranged on the other end surface of the mounting plate (331), and the driving end of the first driving member (341) is connected with the sliding plate (342) through a connecting frame (343).

5. The bimetallic feeding device according to claim 4, wherein the second movable driving assembly (350) comprises a second driving member (351) and a lifting plate (352), the sliding plate (342) is provided with a second sliding rail (370) extending vertically, the lifting plate (352) is mounted on the second sliding rail (370), the second driving member (351) is arranged on the sliding plate (342) and located at the upper end of the second sliding rail (370), and the driving end of the second driving member (351) is connected with the lifting plate (352).

6. The bimetallic strip feeding device according to claim 5, wherein the material moving mechanism (300) further comprises two first buffer assemblies (380), the two first buffer assemblies (380) are respectively arranged on the rack (320), the two first buffer assemblies (380) are respectively arranged at two ends of the first sliding rail (360), and the two first buffer assemblies (380) can be separated and abutted against the mounting plate (331).

7. The bimetallic strip feeding device according to claim 6, wherein the moving mechanism (300) further comprises a second buffer member (390), the second buffer member (390) is disposed on the sliding plate (342) and located at the upper end of the second sliding rail (370), and the second buffer member (390) is detachably abutted against the lifting plate (352).

8. The bimetallic strip feeding device according to one of the claims 1 to 7, wherein the guide rail mechanism (200) further comprises a limiting assembly (220), one end of the guide rail (210) close to the material moving mechanism (300) is provided with a material preparation station (211), and the limiting assembly is arranged at the front side of the material preparation station (211).

9. The bimetallic feeding device according to claim 8, wherein the limiting assembly (220) comprises a fourth driving member (221), a top pillar (222) and a pushing pillar (223), the top pillar (222) is slidably arranged on the end surface of the guide rail (210), the fourth driving member (221) is fixed on one side of the guide rail (210), the pushing pillar (223) is arranged at the driving end of the fourth driving member (221), the pushing pillar (223) is matched with the top pillar (222),

the push column (223) is abutted against the top column (222) by the driving of the fourth driving piece (221), so that the top column (222) penetrates through the guide rail (210) and protrudes out of the end face of the guide rail (210).

10. The bimetal feeding device according to claim 9, wherein the top post (222) is provided at a lower end thereof with a first inclined surface (2221), and the push post (223) is provided at an upper end thereof with a second inclined surface (2231) matched with the first inclined surface (2221).

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